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transcript
MV Grand Manan Adventure
Independent Review of the Reliability of
the Main Propulsion Machinery Prepared by: Shawn Marshall – Director of Marine Operations – GNL
In consultation with: Max Harvey – Assistant Deputy Minister Marine Services – GNL Stephen Mulrooney – Director of Fleet Renewal – GNL
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Table of Contents
Introduction Page 2
Methodology Page 3
Findings Page 4
Conclusion Page 6
Recommendations Page 7
Appendices
Appendix 1 Letter from Deputy Minister Sadie Perron Convening the Technical Evaluation of
the MV Grand Manan Adventure Appendix 2 Sample Engine Room Log Book Entries Including “Constant Speed Mode” Operation & “Combinator Mode” Operation
Appendix 3 EMD Service Advisory – Light Load Conditions
Appendix 4 Main Engine Failure History Report as supplied by operator
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Introduction
At the request of the Department of Transportation & Infrastructure, Government of New
Brunswick, the Marine Services Division of the Department of Transportation & Works,
Government of Newfoundland & Labrador, performed an independent review of the design,
build, operation, and reliability of the MV Grand Manan Adventure, specifically focusing on the
failures that have plagued the main propulsion machinery onboard the vessel since it first
entered service in July 2011. The mandate of the technical review is to specifically address the
following questions:
1. Were the performance criteria laid out in the design & build contract appropriate for the
type of vessel and service?
2. Did the propulsion machinery supplied by Eastern Shipbuilding Group Inc. meet the
performance criteria found in the contract and were they consistent with industry
standards at the time of the build?
3. Are the operating procedures of Coastal Transport Ltd. compatible with the design of
the vessel and its machinery?
4. Are the operational, maintenance, and / or repair procedures of Coastal Transport Ltd.
having an impact on the reliability of the vessel?
The MV Grand Manan Adventure is an 86 meter RO‐RO type passenger ferry designed and built
by Eastern Shipbuilding Group Inc. at their shipyard located in Panama City, Florida. The vessel’s
design utilizes two EMD 710 series 12 cylinder 2‐stroke medium speed marine diesel engines
that produce a total of 6000bhp. The engines drive two Berg controllable pitch propellers
guided by high lift rudders. Auxiliaries include three Caterpillar C‐18 500KW diesel generator
sets, two 600KW shaft generators, and two athwart ship tunnel bow thrusters.
Since entering service in 2011, both main engines have experienced multiple catastrophic
failures that have taken the vessel out of service. The details of the failures are as follows:
Port Main Engine
July 2013 – Main Engine turbocharger clutch failed during operation.
June 2014 – Cast lubricating oil line in turbocharger failed during operation.
August 2014 – Cylinder #6, cylinder liner failed during operation.
March 2015 – Cylinder # 3, cylinder head failure during operation.
April 2015 – Cylinder #4, exhaust valve failure during operation.
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July 2015 – Cylinder #8, exhaust valve failure during operation.
August 2015 – Cast lubricating oil line in turbocharger failed during operation.
Starboard Main Engine
March 2014 – Cast lubricating oil line in turbocharger failed during operation.
April 2014 – Turbocharger gear train failure during operation.
June 2015 – Jacket water cooling pipe to cylinder #6 failed during operation.
This report shall discuss the relevant data contained in the various documents received from
both the operator and the owner and conclude with recommendations, based on that data, in
an attempt to improve the reliability of the main propulsion machinery. The relevant data was
obtained from document review and interviews including, but not limited to:
Engine room log book entries from July 2011 – August 2015.
Detailed design documentation including the contract with the shipbuilder and the
electrical load analysis.
Detailed test and trial documentation including fuel and sea trial data.
Various failure reports provided by the operator.
OEM service reports.
OEM service bulletins.
Maintenance reports.
Work order history.
Data collected during onsite attendance.
Statements from the operator including crew and shore personnel.
Statements from the owner’s representatives including relevant consultants.
Various email correspondence between the operator and OEM authorized
representatives.
Methodology
The study began with a review of the design & build contract between the Department of
Transportation & Infrastructure and Eastern Shipbuilding Group Inc. with specific attention paid
to the decision making process surrounding the selection of the EMD 710 series marine diesel
engines as the main propulsion machinery for the MV Grand Manan Adventure, and the
engine’s suitability for this specific application. Following the review of the design criteria,
research then focused on the reported failures affecting the main propulsion machinery.
As the MV Grand Manan Adventure appeared to have operated relatively problem and
symptomatic free from its entry into service in July 2011 until the first recorded failure of a
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turbocharger in July 2013, the initial approach was to review the relevant engine room log book
data and service conditions prior to July 2013 and compare the findings with the engine room
log book data, service conditions, and service reports just prior to and subsequent to the July
2013 failure in an attempt to identify any significant changes in operation or abnormalities that
could point to the cause of the various failures.
To obtain an accurate history of the main engines and their operating condition, a review of the
maintenance records and maintenance history was also performed to identify any irregularities
or variances from the manufacturer’s recommendations that may have attributed to the
various main engine failures.
Upon completion of a review of the relevant operating data, site visits were conducted onboard
the vessel, as well as visits to the offices of Coastal Transport Ltd., and the Department of
Transportation & Infrastructure. The purpose of these site visits was to interview the
stakeholders and view the operation of the affected machinery first hand in order to verify
thedata contained in the engine room log book. In addition, the operating practices and
conditions of the vessel were observed in a relatively calm sea state.
Following the site visits, an in‐depth review of all of the relevant data including log book entries,
service reports, witness statements, OEM design data, and data collected from the onsite visits
was completed.
Findings
A review of the design & build contract uncovered no notable issues in regards to the
performance criteria or the main propulsion machinery requirements. While the contract could
have been more detailed and prescriptive in requirements, it did represent a reasonable
standard of performance given the nature of the service.
The EMD 710 series marine diesel engines appear to have adequately met the performance
requirements of the contract. Interviews with key Department of Transportation &
Infrastructure staff members indicate the engine selection process appeared to be based solely
on a recommendation from the shipbuilder, Eastern Shipbuilding Group Inc., whose
recommendation appeared to be influenced mainly on lead times associated with the delivery
of new marine diesel engines at the time of the build in addition to a pre‐established
relationship between the shipbuilder and the engine manufacturer; which is not uncommon in
the shipbuilding industry.
A look at the maintenance records, and maintenance history provided by both the operator and
the owner, in comparison to the manufacturer’s recommendations, did not identify any
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variances or irregularities. There was no evidence to support a finding that poor maintenance
practices had contributed to the failures.
The maintenance records provided by the owner were in the form of an annual report received
from the operator as per the existing agreement. The report simply indicates what major tasks
were completed as well as containing a print out from the operator’s maintenance
management program. Aside from this report there is little to no oversight from the owner
when it comes to maintenance, vessel operation, or major repairs.
Upon review of the relevant data associated with the failures, beginning in July 2013, there
appear to be several influencing factors that may have attributed to the various failures. The
data, as well as statements from the operators, indicate that from the vessel’s entry into service
in July 2011 up until the initial turbocharger failure in July 2013, the vessel had been operating
in constant speed mode at 900 RPM not only while in transit but also while secured at the dock
during loading and unloading operations. As a result there were several periods of
approximately 30 minutes (the length of time between arrival and departure) throughout the
day, in which the main engines were running at 900 RPM with little to no load on them.
The result of this “no‐load operation” was that the turbocharger clutch assembly was likely
engaged for extended periods of time reducing its life expectancy. EMD released a service
advisory in October 2010 advising against this very practice. As a result of the failure, the
operator changed the practice of remaining at 900 RPM while secured to the dock and began
reducing the main engines to idle speed when not in transit. Since that change in procedure,
there has been no other reported failure of this nature; this supports the recommendations and
findings of the service bulletin issued by EMD in 2010.
The vessel underwent a scheduled refit during the autumn of 2013. At that time the operators
elected to set up and employ a “combinator mode” on the vessel which would match propeller
pitch settings with a predetermined engine speed to try and maintain a balanced load on the
main machinery. Prior to this “combinator mode”, the vessel had only been set up to operate in
“constant speed mode” which would maintain the engine speed at a constant 900 RPM no
matter what the propeller pitch demand was; this mode is normally intended to utilize shaft
generators in supplying electrical power to the vessel which require a constant RPM in order to
provide reliable power.
Following the commencement of the “combinator mode”, various crew members, including
one Master, indicated that there was a noticeable vibration present at main engine speeds
below 900 RPM. The failures that occurred subsequent to the turbocharger clutch failure of July
2013 all appear to be that of a nature that suggests a possible vibration issue. During the site
visit, it was observed that a slight vibration could be felt adjacent to the port main engine. Iin
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addition, when the vessel was put in “combinator mode”, a vibration was evident throughout
the vessel.
Upon review of the engine room log book data, it is apparent that there is a difference in how
the vessel is operated. Masters have discretion on the mode and had different mode
preferences for operation. There appeared to be a pattern in which the vessel was operated for
an extended period in “constant speed mode” and then changed to operate for an extended
period in “combinator mode”. There was an extended period prior to each failure in which the
vessel was operated in “combinator mode”.
Given the fact that the vessel operated for the first 2 years of its life in “constant speed mode”
with no major reported issues, combined with the witness statements and observations made
during the site visit, it is reasonable to suggest that the vibration caused while operating in
“combinator mode” is a major contributing factor to the subsequent failures and is detrimental
to the reliability of the main propulsion machinery.
During the site visit it was observed that there was a substantial imbalance between the port
and starboard main engines. Review of the operating pressures and temperatures, as well as
the fuel demand and consumption, indicated that the starboard engine appeared to be
“carrying more load”, for the same amount of pitch on the propellers, than the port engine.
This in itself may prove detrimental to the reliability of the vessel if allowed to exist for an
extended period of operation.
Although fuel consumption was not part of the original scope of this review, it was presented as
an issue on numerous occasions by the owner’s representatives. It goes without saying that
running the engines and vessel at a slower speed will reduce the fuel consumption, however
evidence has demonstrated that the reliability of this particular vessel is reduced as long as the
main engines are run at speeds below 900 RPM with the current arrangement.
Conclusion
The EMD 710 marine diesel engines met the requirements of the design and build contract,
therefore an argument to replace these engines is not supported.
Evidence indicates that there is no inherent problem with the existing main propulsion
machinery, nor does there appear to be any link between the various failures and the
maintenance practices of the operator. However it is apparent that there is a direct link
between the failures and the manner in which the vessel is being operated. Vibration levels
found during certain modes of operation appear to be substantial enough to cause recurring
issues with the main engines.
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Recommendations
Immediate
it is recommended that the vessel, given its current configuration, operate in “constant speed
mode” as opposed to “combinator mode”. The main engines should be reduced to “idle
speed” or shut down while in port. The evidence shows that vibrations occurring while in
“combinator mode” have been harmful to the machinery, prolonged operation in this mode will
likely cause further issues and reduced reliability. The “combinator mode” should not be used
on this service in the current configuration.
It is recommended that the owners request the operators to employ a Vibration Analysis
Technician to perform an in depth vibration analysis on the main propulsion machinery to
identify and correct any vibration related issues.
Short Term (Within one year)
It is recommended that the owner requests the operator to task OEM service representatives
for EMD and the Berg propeller systems to balance out the loading on the main engines and
calibrate the load management system onboard. In order for this to be done properly,
manufacturers’ representatives for both systems should be onsite at the same time. This
should allow return to “combinator mode” operation which would reduce fuel consumption.
It is recommended that the owner request the operator to enroll in a routine vibration analysis
program, once any existing vibration issues are corrected, to maintain the condition of the
machinery plant. This will help improve the reliability of the vessel, and move towards a
“preventative maintenance” routine as opposed to a “reactive maintenance” routine.
It is recommended that maintenance records should be forwarded to, and reviewed by, the
owner no less than “quarterly” to ensure compliance with the OEM maintenance schedules.
It is recommended that the owner have a representative attend the vessel no less than
“quarterly” to witness and review vessel operation. Had this been practiced prior to this report,
the pattern that emerged in regard to the change in operating modes may had been discovered
earlier, resulting in less “downtime”.
Medium Term (By end of scheduled refit)
It is recommended that the owner consider adding a technical and operational capability within
its organization to oversee and monitor the contractor and the operation. This due diligence
will promote greater, and earlier, operational and technical insight into the service. A more
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informed and involved owner, when it comes to the operation, maintenance practices, and
repair procedures onboard their vessel, will promote increased reliability and sustainability of
the service.
It is recommended that the current switchboard configuration be modified to permit the shaft
generators to provide electrical service for the entire vessel. The current electrical supply
system consists of three diesel auxiliaries and two shaft driven generators. The shaft generators
are currently only utilized for supplying power to the bow thrusters while maneuvering. The
remainder of the vessel’s electricity is supplied by operating two of the diesel driven Caterpillar
generators. If incorporated into the power management system, the shaft generators could
provide the bulk of the electrical requirements with the diesel auxiliaries supplementing the
power on an as needed basis. This would drastically reduce the fuel being consumed by the
diesel auxiliaries as well as provide a load for the main engines while the vessel is secured to
the dock. Any main engine not being utilized to provide power to the vessel should be reduced
to idle, or ideally, shut down, between crossings.
Appendices
Appendix 1
Letter from Deputy Minister Sadie Perron (GNB) Convening the Technical
Evaluation of the MV Grand Manan Adventure
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Appendix 2
Sample Engine Room Log Book Entries Including “Constant Speed Mode”
Operation & “Combinator Mode” Operation
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Appendix 3
EMD Service Advisory – Light Load Conditions
SA#: 10-026 REVISION: Original REVISION DATE: ISSUE DATE: 6/25/10 AUTHOR:Customer Engineering • Electro-Motive Diesel, Inc. • 9301 W. 55th Street • LaGrange, IL 60525
SERVICE ADVISORY - 710 Light Load Operation and Inspection Form CEF-001 Rev B. 7/1/2006
Page 1 Copyright © Electro-Motive Diesel, Inc.. All rights reserved. Neither this document, nor any part thereof, may be reproduced or reprinted without the prior written consent of the Electro-Motive Diesel, Inc.. Contact EMD SDO office.
Components Affected: 12, 16, and 20 cylinder Model 710 Turbocharged Engines in Generator Service or Synchronous Operation Purpose: To reiterate the consequences of light load operation and provide an inspection guideline for turbocharger gear trains that have been subjected to excessive high driving torque Background: EMD engines, like other internal combustion engines, operate most efficiently when producing the power for which they were designed. Under normal operating conditions load can vary based on environmental conditions and equipment demands. Power Plant Load Management systems can and should be designed to minimize the number of engines on line at any time in order to maximize load, optimize fuel economy, and minimize any issues related to light load. The rapid response of the EMD two-cycle engine allows for fewer engines to be on line at any time to meet transient power requirements*. Under typical drilling operations EMD engines provide durable and reliable performance for operators. Recent failures of EMD turbochargers with relatively low operating hours have identified a potential problem which we believe to be attributed to extremely light load operation during the construction and testing phases of equipment. The practice of using main engines for hotel power during construction in the shipyards has been identified as a leading contributor to early wear of drive gears and turbocharger failures. Shipyard practices of running engines for hotel power during construction of the vessel/ drilling unit should be avoided. As a general rule load management systems for Model 710 turbocharged engines running at 750 or 900 RPM should not be less than 30% of the full load rating for optimum life. There is no minimum load restriction for operation at lower engine speeds. SA#: 10-026 REVISION: Original
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REVISION DATE: ISSUE DATE: 6/25/10 AUTHOR:Customer Engineering • Electro-Motive Diesel, Inc. • 9301 W. 55th Street • LaGrange, IL 60525
SERVICE ADVISORY - 710 Light Load Operation and Inspection Form CEF-001 Rev B. 7/1/2006
Page 2 Copyright © Electro-Motive Diesel, Inc.. All rights reserved. Neither this document, nor any part thereof, may be reproduced or reprinted without the prior written consent of the Electro-Motive Diesel, Inc.. Contact EMD SDO office.
* EMD is available to assist in optimizing power plant load management systems with our two cycle engines. Under typical operating conditions it is normal for high driving torque to be transmitted through the turbo gear train for a short time. As the engine load is applied, the power needed to mechanically drive the turbo is proportionally decreased on the gear train by the turbine. The turbine uses exhaust gas energy to decrease the gear train load. At approximately 70% of full rated load, the exhaust energy is sufficient to drive the turbocharger rotating assembly without any gear train assist. At this operating condition, the overrunning clutch allows the turbo to speed up and run independent of the gear train: the gears continue to turn at their corresponding speed ratio to engine RPM without transmitting torque. If engines are operated for extended periods at full speed with light loads, turbo gear train wear is accelerated. At loads of 30% and above there is no significant wear on the drive gears and EMD expects full turbocharger life. At loads below 30% wear rates gradually increase, however operating the engines during construction where loads could easily be below 10% load for sustained periods of time the wear rates could reduce the life of the drive gears to 3000 hours of operation. EMD engines operated at full speed and less than 20% load can experience oil accumulation in the exhaust system. Engines equipped with Low Lube Oil power assemblies or engines that carry a US EPA Tier 2 certification will experience less accumulation. The exhaust system can be cleaned out by operating the engines at 70% load or more for at least 30 minutes. This should be performed after 8 hours of idling or 100 hours of continuous operation at synchronous speed with less than 20% load. Recommended Action: 1. Change any operational activities that allow engines to operate at light loads for extended periods of time such as construction. 2. If it is suspected that engines have already been operated under very lightly loaded conditions, it is
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recommended that an inspection of the gears be made to insure the gears have not worn to a point where a failure would ensue. The following can be indicators of early stage turbocharger gear train failure due to light engine loading: • Noise generated from worn involute turbo spur gears will be louder than a turbo with unworn gears • Visual wear on Turbo Spur Gears SA#: 10-026 REVISION: Original REVISION DATE: ISSUE DATAUTHOR:Customer Engineering • Electro-Motive Diesel, Inc. • 9301 W. 55th Street • LaGrange, IL 60525
SERVICE ADVISORY - 710 Light Load Operation and Inspection Form CEF-001 Rev B. 7/1/2006
Page 3 Copyright © Electro-Motive Diesel, Inc.. All rights reserved. Neither this document, nor any part thereof, may be reproduced or reprinted without the prior written consent of the Electro-Motive Diesel, Inc.. Contact EMD SDO office.
Inspection Procedure: Recent inspections of turbochargers have shown that the turbo spur gears are failing as a result of high turbocharger gear train loads. The gears at risk are the carrier drive, idler, and turbo drive gear, see figure 1 below. Figure 1-Turbocharger Gear Train Inspect these 3 gears SA#: 10-026 REVISION: Original REVISION DATE: ISSUE DATE: 6/25/10 AUTHOR:Customer Engineering • Electro-Motive Diesel, Inc. • 9301 W. 55th Street • LaGrange, IL 60525
SERVICE ADVISORY - 710 Light Load Operation and Inspection Form CEF-001 Rev B. 7/1/2006
Page 4 Copyright © Electro-Motive Diesel, Inc.. All rights reserved. Neither this document, nor any part thereof, may be reproduced or reprinted without the prior written consent of the Electro-Motive Diesel, Inc.. Contact EMD SDO office.
1. Ensure that the engine is not running and the appropriate lock outs are in place 2. Remove the aux gen cover plate on the RB side of the turbocharger as depicted in figure 2 below. Figure 2 3. Use the exposed opening as an access point for viewing the gears as shown in figure 3 below. Figure 3 The following can be indicators of early stage turbocharger gear train failure due to light engine loading: • Visual wear on Turbo Spur Gears (Turbo Drive Gear, Turbo Idler Gear, Carrier Drive Gears) See Figures 6 & 7 on page 6 • Loose, broken, or missing Oil Lube Jumper Bolts Remove Aux Gen Cover Plate Aux Gen
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Cover Plate Removed SA#: 10-026 REVISION: Original REVISION DATE: ISSUE DATE: 6/25/10 AUTHOR: Customer Engineering • Electro-Motive Diesel, Inc. • 9301 W. 55th Street • LaGrange, IL 60525
SERVICE ADVISORY - 710 Light Load Operation and Inspection Form CEF-001 Rev B. 7/1/2006
Page 5 Copyright © Electro-Motive Diesel, Inc.. All rights reserved. Neither this document, nor any part thereof, may be reproduced or reprinted without the prior written consent of the Electro-Motive Diesel, Inc.. Contact EMD SDO office.
Due to space limitation, you may only be able to view of the turbo drive gear, idler gear, and the jumper bolts (Reference Figures 4 & 5 below). Figure 4 Figure 5 Turbo Drive Gear Turbo Idler Gear Oil Lube Jumper Bolts SA#: 10-026 REVISION: Original REVISION DATE: ISSUE DATAUTHOR:Customer Engineering • Electro-Motive Diesel, Inc. • 9301 W. 55th Street • LaGrange, IL 60525
SERVICE ADVISORY - 710 Light Load Operation and Inspection Form CEF-001 Rev B. 7/1/2006
Page 6 Copyright © Electro-Motive Diesel, Inc.. All rights reserved. Neither this document, nor any part thereof, may be reproduced or reprinted without the prior written consent of the Electro-Motive Diesel, Inc.. Contact EMD SDO office.
4. Inspect at the surface of the gear flanks (called involute). On the involute check for signs of pitting/scoring/scuffing. (Reference Figure 6 & 7 below) Figure 6 Figure 7 5. Replace the aux gen cover plate on the RB side of the turbocharger. 6. If light loading damage is confirmed as outlined in this document it is recommended that the engines not be operated to avoid more serious failures that can damage the entire gear train. Contact your licensed EMD distributor for resolution. Pitting above the pitch line area accompanied by scuffing near the tip Pitting on the pitch line on one side of the gear face farther away from the impeller Pitting above the pitch line area accompanied by scuffing near the root Scuffing near the
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root (dedendum) Scuffing at the tip SA#: 10-026 REVISION: Original REVISION DATE: ISSUE DATE: 6/25/10 AUTHOR: Customer Engineering • Electro-Motive Diesel, Inc. • 9301 W. 55th Street • LaGrange, IL 60525
SERVICE ADVISORY - 710 Light Load Operation and Inspection Form CEF-001 Rev B. 7/1/2006
Page 7 Copyright © Electro-Motive Diesel, Inc.. All rights reserved. Neither this document, nor any part thereof, may be reproduced or reprinted without the prior written consent of the Electro-Motive Diesel, Inc.. Contact EMD SDO office. (For EMD Office Use Only) Approvals (Required): Approval Needed Y N Approver Approved Y N Approved By Date CES/CEM 6/25/10 Warranty Marketing Service Advisory – General Classification (Select All that Apply): GENERAL INFORMATION: This document is being issued to provide general information to the Customer Care Field Organization. REQUEST FOR FIELD SUPPORT: This document is being issued to request Customer Care Field resources for the purpose of information/data collection in support of a current field issue investigation. PRELIMINARY: This document is being issued to provide notable preliminary findings with regard to a current field issue. It will be followed by the issuance of an appropriate revision, or revisions, as the investigation progresses through closure, or more information becomes available. FINAL: This document is being issued to provide final findings and recommendations on the proper handling of a current field issue. This document is
intended to provide official closure of the subject field issue.
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Appendix 4
Main Engine Failure History Report as Supplied by the Operator
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